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Supporting Multiple Quality-of-Service Classes in IEEE 802.16e Handoff
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Author(s): Melody Moh (San Jose State University, San Jose, CA, USA)and Teng-Sheng Moh (San Jose State University, San Jose, CA, USA)
Copyright: 2010
Pages: 20
Source title:
Quality of Service Architectures for Wireless Networks: Performance Metrics and Management
Source Author(s)/Editor(s): Sasan Adibi (University of Waterloo, Canada), Raj Jain (Washington University in St. Louis, USA), Shyam Parekh (Alcatel-Lucent, USA)and Mostafa Tofighbakhsh (AT&T Labs, USA)
DOI: 10.4018/978-1-61520-680-3.ch013
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Abstract
IEEE 802.16 WiMAX (Worldwide Interoperability for Microwave Access) is a major standard technology for Wireless Metropolitan Area Networks (Wireless MAN). Quality-of-service (QoS) scheduling class and mobility management are two main issues for supporting seamless high-speed data and media-stream communications. Previous works on WiMAX handoff however have mainly addressed a particular scenario or a single QoS class. This chapter first presents an overview of the QoS scheduling classes supported by the IEEE 802.16 standard, followed by a survey of major related works proposed to enhance 802.16e handoffs. Next, it will present a new context-sensitive handoff scheme that supports the five 802.16 QoS scheduling classes, and is energy-aware – it may switch to energy-saving mode during handoff. It will then illustrate performance evaluation, which will show that, compared to three existing methods, the proposed scheme successfully supports the five QoS classes in both layers 2 and 3 handoff, decreases end-to-end handoff delay, delay jitter, and service disruption time; it also increases throughput and energy efficiency. Finally, key implementation and cost issues are discussed. We believe that this chapter is a significant contribution for providing high-quality, seamless data and media streaming over 802.16 as well as LTE (Long-Term Evolution) cellular networks, and would be a valuable part of QoS architectures in the wireless networking domain.
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